Nonstop traffic system using half (1/2) cloverleaf and traffic method applied with the same

ABSTRACT

Disclosed is a nonstop traffic system using a half (½) cloverleaf and a traffic method applied with the same, including a loop-type traffic system for connecting a half (½) cloverleaf ( 100 ) to half (½) underground U-turn lanes ( 200 E,  200 W,  200 S and  200 N) that can make vehicles drive and pedestrians walk nonstop in every direction without relation to traffic signals at existing intersections or roadways for left-turn and U-turn, and crosswalks. The half (½) cloverleaf ( 100 ) is constructed at existing intersections and the half underground U-turn lanes ( 200 E,  200 S,  200 S and  200 N) are constructed on left-turn roadways in existing four directions (East, West, South and North) that connect to the intersections, U-turn roadways and crosswalks. As mentioned, all structures in the nonstop traffic system using the half (½) cloverleaf in a loop-type that connects the half (½) cloverleaf ( 100 ) to the half (½) underground U-turn lanes ( 200 E,  200 W,  200 S and  200 N) in four directions (East, West, South, North) is adopted to the bisectional construction method, thus the height of all lanes can be differentiated. As mentioned, the half (½) cloverleaf ( 100 ) includes a half (½) overpass ( 10 ), a half (½) underpass ( 20 ), a half (½) underground U-turn roadway ( 30 ) and a half (½) ground pedestrian bridge ( 40 ). Moreover, the half (½) underground U-turn lanes ( 200 E,  200 W,  200 S and  200 N) includes a half (½) overpass ( 50 ), a half (½) underground U-turn roadways ( 60 ) and half (½)

DETAILED DESCRIPTIONS OF THE INVENTION Invention Related Technology

The present invention relates to a nonstop traffic system using a half (½) cloverleaf and a traffic method applied with the same, and more particularly, to a nonstop traffic system and a traffic method applied with the same that can reduce traffic jams or traffic accidents that may be caused at existing intersections or left-turn roadways in four directions (East, West, South and North), U-turn roadways and crosswalks, by constructing a half (½) cloverleaf (100) at existing intersections and constructing half (½) underground U-turn lanes (200E, 200W, 200S and 200N) on left-turn lanes constructed on existing roadways in existing four directions (East, West, South and North) according to a loop-type traffic system for connecting a half (½) cloverleaf (100) with half (½) underground U-turn lanes (200E, 200W, 200S and 200N), thereby preventing vehicles from stopping at the existing intersections, left-turn roadways and U-turn roadways, and preventing pedestrians from stopping on crosswalks all the time.

Left-turn is prohibited on the half (½) cloverleaf (100) and the half (½) underground U-turn lane (200E, 200W, 200S and 200N).

On the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) constructed in four directions, it allows vehicles not to make a left turn or a U-turn on the half (½) cloverleaf (100) to go straight after making a U-turn on the half (½) underground U-turn roadway (60) of the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) and then to go straight or make a right turn or make a U-turn on a half (½) underpass (20) or a half (½) underground U-turn roadway (30) of the half (½) cloverleaf (100). In other words, according to the present invention, in comparison with the existing intersection, on which vehicles can make a leaf turn or make a U-turn according to a traffic signal, the adoption of bisection construction method allows vehicles to make a left turn or make a U-turn nonstop without traffic signals.

TECHNOLOGICAL ADVANTAGE OF THE INVENTION

Generally, a traffic system of existing roadways consists of 6-lane to 8-lane, constructed in parallel in other to allow vehicles to go straight, make a left-turn, a right-turn and a U-turn on the crossroad.

Moreover, a straight roadway and right-turn, left-turn, U-turn roadways or crosswalks are formed to allow vehicles or pedestrians to divide or walk in order according to the traffic signals

At the existing intersection vehicles can take a right-turn irrespective of a right-turn signal, But the driver is sure to drive a car according to the right-turn and go signals for left-turn or go-straight when turning left or going straight at the intersection.

In this case, a drive signal and a stop signal are provided in turn according to the signals of a traffic light, When vehicles are driving on any one roadway, they are surely stopping on other three roadways.

Accordingly, a vehicle on a roadway in one side waits for a traffic signal to change at least one time to drive in a desired direction and thus it disturbs the flow of traffic largely.

Moreover, when a traffic light goes wrong or an accident happens, left turning and going straight vehicles get confused, therefore it brings about the bad flow of traffic, traffic jams and traffic accidents.

Due to the existing traffic system, time for waiting for a traffic signal becomes relatively longer, thus it causes a waste of fuel and air pollution that becomes worse locally.

According to the existing traffic system, at an intersection or on a left-turn roadway and a U-turn roadway, the first lane is for left-turning or U-turning vehicles, the second lane for left-turning or going-straight vehicles, the third lane for going-straight vehicles and the fourth lane for right-turning vehicles.

A vehicle driving on the first or the second lane at a long distance can go straight by changing the lane onto the second or the third lane while approaching an intersection, left-turn or U-turn roadways, Thus, it brings about a traffic jam and traffic accidents due to a bad flow of traffic caused by lane-changing of vehicles near the intersection, the left-turn or U-turn roadways.

DISCLOSURE [Technical Problems]

Accordingly, an object of the present invention is to provide a nonstop traffic system using a half (½) cloverleaf and traffic method applied with the same that can make a vehicle keep driving nonstop and a pedestrian keep walking nonstop on each lane by constructing a half (½) cloverleaf (100) at existing intersections and half (½) underground U-turn lanes (200E, 200W, 200S and 200N) on left-turn roadways, U-turn roadways and crosswalks of roadways in existing four directions (East, West, South and North), in order words, by adopting a bisection construction method that can divide one structure, for example, the half (½) cloverleaf (100) and the half (½) underground U-turn lanes (200E, 200W, 200S and 200N), into two sections and then make one half exposed on the ground and the other covered underground to differentiate the height of lanes, and that can make easier the construction of the half (½) cloverleaf (100) and the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) in existing narrow spaces.

The lanes of the half (½) cloverleaf (100) and the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) are divided for going-straight and rotation vehicle, thus it allows vehicles to go straight, make a right-turn and a U-turn nonstop, pedestrians to take the crosswalk nonstop without difficulty in other lanes.

[Technical Solutions]

According to an aspect of the present invention, there is provided a nonstop traffic system using a half (½) cloverleaf (100), At an existing intersection a half (½) cloverleaf (100) consisting of bisectional structures is constructed and half (½) underground U-turn lanes (200E, 200W, 200S and 200N) are constructed on left-turn roadways, U-turn roadways and crosswalks of roadways in existing four directions (East, West, South and North).

On the half (½) cloverleaf (100) and the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) in four directions (East, West, South and North), the first and second central lanes of a half (½) overpass (10) or half overpass (50) are constructed at the height equivalent to half of that in an existing overpass.

On the half (½) cloverleaf (100) and the half (½) underground U-turn lanes (200E, 200W, 200S and 200N), a half (½) underpass (20), a half (½) underground U-turn roadway (30), and a half (½) underground U-turn roadway (60) are constructed at the depth equivalent to half of that of an existing underpass.

On the half (½) cloverleaf (100), a half (½) ground pedestrian bridge (40) in the shape of “H” may be constructed or a half (½) underground crosswalk (70) in the shape of “I” may be constructed on the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) in four directions (East, west, south and North).

Accordingly, all pedestrians can walk nonstop without interference of going-straight and U-turning vehicles.

The half (½) ground pedestrian bridge (40) of the half (½) cloverleaf (100) may be constructed at the intersection of the top height (about 4.50 m above the floor of the half (½) underpass (20) of a median strip of the half underpass (20) and the surface in the horizontal direction.

A vehicle driving on the half (½) overpass (10) goes straight at the height of 4.50 m from the half (½) ground pedestrian bridge (40) and a vehicle driving on the half (½) underpass (20) goes straight half (½) underground at the depth of 4.50 m above the half (½) ground pedestrian bridge (40). Thus, all pedestrian can walk nonstop without interference of vehicles that are driving in four directions.

The half (½) underground crosswalk (70) of the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) is constructed at the depth (approximately 3.00 m underground) of the half (½) underground U-turn roadway (60) that is perpendicular to the half (½) overpass (50) and connected to sidewalks in both directions. Thus, all pedestrians can walk nonstop without interference of vehicles that are going straight or making a U-turn on the half (½) overpass (50) or the half (½) underground U-turn roadway (60).

The bisectional construction method. adopted according to the present invention, the height and depth of lanes of each roadway may be differentiated to reduce the size of each structure and the lanes may have different structures to allow vehicles to go straight, make a right turn and U-turn, and pedestrians to take the crosswalk nonstop all the time without obstacles to other lanes. Thus, it can solve traffic problems that may happen at existing intersections or left-turn road in four directions (East, West, South and North). U-turn road and crosswalks.

In a traffic system of existing intersection, when driving from North to South, a vehicle crosses the roadway according to a left-turn signal on first and second lanes of the existing intersection and advances to the northern destination.

However, if driving from the half (½) underground U-turn lane (200W) to the half (½) underground U-turn lane (200N) according to the present invention, a vehicle may arrive on a destination that is the half (½) underground U-turn lane (200N) nonstop, when going straight on the half (½) underground U-turn lane (200W), going straight on the half (½) underpass (20) constructed on the first and second lanes of the half (½) cloverleaf (100), taking an U-turn at a U-turn point of the half (½) underground U-turn roadway (60) constructed on the third and fourth lanes of the half (½) underground U-turn lane (200E) in front, going straight in its opposite direction, entering the half (½) underpass (20) constructed on the third and fourth lanes of the half (½) cloverleaf (100) and then going straight on the half (½) underground U-turn roadway (30) constructed on the third and fourth lanes of half (½) cloverleaf (100).

The nonstop traffic system using the half (½) cloverleaf (100) and the traffic method applied with the same may substitute for an existing left-turn function by allowing a vehicle to take a U-turn on the half (½) underground U-turn roadway (60) constructed on the third and fourth lanes of the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) in four directions (East, West, South and North) then to go straight and take a right turn on the half underpass (20) or the half (½) underground U-urn roadway (30) of the half (½) cloverleaf (100) in front, eventually to get to the destination, on the half (½) cloverleaf (100) constructed at the existing intersections.

The bisection construction method of the dichotomy, adopted according to the present invention, can divide one structure, for example, the half (½) cloverleaf (100) and the half (½) underground U-turn lanes (200E, 200W, 200S and 200N), into two sections, upper and lower portions, and then make the upper portion exposed on the ground and the lower covered underground, and it can reduce the size of structures of existing overpasses or underpass by half, which makes a vehicle approach the roadways easily, and easy to construct in any place for its good economical efficiency. Moreover, the height and depth of each lane is differentiated in allowing a vehicle to go straight, make a right turn and U-turn, and pedestrians to take the crosswalk nonstop all the time without any obstacles to the other lanes.

EFFECTS OF THE INVENTION

As described above, the nonstop traffic system using the half (½) cloverleaf and the traffic method applied with the same according to the present invention produce the following effects.

First, the height and depth of each lane on the half (½) cloverleaf (100) and the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) is differentiated to allow a vehicle to drive in one direction independently, in other words, to go straight, make a right turn and U-turn, and pedestrians to take the crosswalk nonstop all the time without obstacles to other lanes, Accordingly, it can improve flow of traffic.

However, if something is wrong with a traffic light, that can be caused by natural disasters or artificial means, in the existing traffic signal system, at existing intersections or left-turn lanes in four directions, U-turn lanes and crosswalks, all vehicles are waiting or left-turning and going-straight vehicle are getting confused. Thus, it can lead to a traffic jam, a traffic congestion and a traffic accident.

Second, the half (½) cloverleaf (100) or the half underground U-turn lanes (200E, 200W, 200S and 200N) can save fuel and improve a flow of traffic without a time for waiting for traffic lights for changing driving directions, Additionally, it can reduce the import of crude oil and the production of carbon dioxide, then cut air pollution locally. It can lead to environmental improvement and solve traffic problems.

Third, if the nonstop traffic system using the half (½) cloverleaf and the traffic method applied with the same are used, the first and second lanes that are closer to the center lane are used for going-straight driving at a long distance, and the third and fourth lanes are used for changing driving direction.

Accordingly, it can reduce car accidents by allowing unskilled or skilled drivers to predict a direction to advance and gain confidence, and can save driving time and allow drivers to be familiar with various matters of traffic operation.

Fourth, the height and depth of lanes are differentiated, that vehicles are driving in each direction at existing scattered intersections or left-turn roadways, U-turn roadways and crosswalks, the vehicles are differentiated to independently drive. Accordingly, it can prevent car accidents in advance and reduce the car accident rate or the number of killed and wounded remarkably, then reduce human power loss or property loss.

When the traffic operation system is consistently applied, it can bring convenience and efficiency and reduce the waste of nation's resource. thus, it can bring a safe traffic system and establish advanced traffic culture.

SIMPLE DESCRIPTION OF THE PLAN

FIGS. 1 and 2 are whole schematic Plan view of a nonstop traffic system using a half (½) cloverleaf (100) according to a desirable exemplary embodiment of the present invention.

FIG. 3 is a plane view of the half cloverleaf (100).

FIG. 4 is a side view of the half cloverleaf (100).

FIG. 5 is a plane view of a half underground U-turn lane (200E).

FIG. 6 is a plane view of a half underground U-turn lane (200W).

FIG. 7 is a plane view of a half underground U-turn lane (200S).

FIG. 8 is a plane view of a half underground U-turn lane (200N).

FIG. 9 is a side view of a half underground U-turn lanes.

DESCRIPTIONS OF THE MAKES IN THE MAJOR PARTS IN THE DRAWINGS

-   (10): half (½) overpass. -   (20): half (½) underpass. -   (30): half (½) underground U-turn roadway. -   (40): half (½) ground pedestrian bridge. -   (50): half (½) overpass. -   (60): half (½) underground roadway. -   (70): half (½) underground crosswalk. -   (100): half (½) cloverleaf. -   (200E, 200W, 200S and 200N) : half (½) underground U-turn lanes.

DETAILED DESCRIPTIONS OF THE INVENTION

Herewith, with reference to the attached drawing, the nonstop traffic system by means of the half (½) cubic crossroad as in the desirable practice ‘yes’ and its applications are described as follows.

Referring to FIGS. 1 and 2, the nonstop traffic system using the half (½) cloverleaf consists of a loop-type traffic system that connects one half (½) cloverleaf (100) with two directions perpendicular each other at an existing intersection to four half (½) underground U-turn lanes (200E, 200W, 200S and 200N) that are constructed in four directions (East, West, south and North) centering around an intersection.

As enlarged and shown as FIG. 3, the half (½) cloverleaf (100) includes a half (½) overpass (10), a half (½) underpass (20), a half (½) underground U-turn roadway (30) and a half (½) ground pedestrian bridge (40), for enabling a vehicle to go straight, take a U-turn and make a right turn nonstop on lanes of each structure and a pedestrian to take the crosswalk.

The half (½) overpass (10) is constructed on a going-straight lane in one direction of the half (½) cloverleaf (100), and the half (½) underpass (20) is constructed on a going-straight in the other direction perpendicular to the direction of the half (½) overpass (10).

The half (½) underground U-turn roadway (30) that is inclined toward the semi-underground on the third and fourth lanes is constructed on right and left sides in parallel, centering around the half (½) overpass (10).

The half (½) ground pedestrian bridge (40) is constructed at a point equivalent to half of the height (9.00 m, the height from the ground of the half (½) underpass (20) to the half (½) overpass (10)) of the half (½) overpass (10) from a point at which the half (½) overpass (10) is perpendicular to the half (½) underpass (20), and at a point that an upper portion (4.50 m, the height from the ground of the half (½) underpass (20)) of the median strip of the half underpass (20) is horizontally contacted to the surface.

When the point is horizontally connected to sidewalks in four directions and the half (½) ground pedestrian bridge (40) is constructed in the shape of “H” (plan view) and “T” (side view), it allows pedestrians to take the crosswalk nonstop in four directions without obstacles to other lanes, thus it can solve traffic problems of existing crosswalk.

The height of first and second lanes on the half (½) overpass (10) that are going-straight lanes in one direction on the half (½) cloverleaf (100) is equivalent to half of the height of an existing overpass.

On the half (½) cloverleaf (100), the depth of the half (½) underpass (20) that is perpendicular to the half (½) overpass (10) or the half (½) underground U-turn roadway (30) that is parallel to the half (½) overpass (10) is equivalent to half of the depth of a existing underpass.

The nonstop traffic system using the half (½) cloverleaf (100) can be established with efficiency and economical efficiency by constructing at least four lanes on both sides centering around the median strip.

On the half (½) cloverleaf (100), when the lanes are called the first, the second and the third lanes that are closer to the center line in order, the first and second lanes allow a vehicle to go straight and the third and fourth lanes allow the vehicle to take a right turn and a U-turn, sometimes, they are used as a bike lane and a stop lane.

On the half (½) cloverleaf (100), a lane for vehicle crossing the lane and making a left turn is originally excluded. Additionally, when an “example” is given for substituting for a left-turn function.

If a vehicle is driving from the half (½) underground U-turn roadway (200S) to the half (½) underground U-turn roadway (200W).

The vehicle is going straight using the half (½) overpass (10) constructed on the first and second lanes of the half (½) cloverleaf (100) after going straight on the half (½) underground U-turn lane (200S), entering onto the half (½) underground U-turn roadway (60) constructed on the third and fourth lanes of the half (½) underground U-turn lane (200N) that is located in front, making a right turn on the half (½) underground U-turn roadway (30) constructed on the third and fourth lanes of the half cloverleaf (100), then going straight on the half (½) underpass (20) constructed on the third and fourth lanes of the half (½) cloverleaf (100). Thus, the vehicle arrives on the half (½) underground U-turn lane (200W).

Additionally, the vehicle enters the half (½) underground U-turn roadway (30) constructed on the third and fourth lanes of the half (½) cloverleaf (100) after going straight on the half (½) underground U-turn lane (200S), making a right turn and going straight, then entering the half (½) underground U-turn roadway (60) constructed on the third and fourth lanes of the half (112) underground U-turn lane (200E) that is located in front, taking a U-turn at a U-turn point and driving, then going straight on the half (½) underpass (20) constructed on the first and second lanes of the half (½) cloverleaf (100). Thus, the vehicle is arriving on the half (½) underground U-turn lane (200W).

The result is the same as a function for enabling a vehicle to make a right turn on the half (½) overpass (10) of the half (½) cloverleaf (100) and then to arrive on the half (½) underground U-turn lane (200W).

If the vehicle drives from the half (½) underground U-turn lanes (200E, 200W and 200N) to the half (½) underground U-turn lanes (200E, 200W, 200S and 200N), it is the same process as that of allowing the vehicle to drive from the half (½) underground U-turn lane (200S) to the half (½) underground U-turn lane (200W)

Referring to FIG. 4, a side view according to the “example” illustrates a side view taken from the half (½) cloverleaf (100) of FIG. 3 that are structures including the half (½) overpass (10), the half (½) underpass (20), the half (½) underground U-turn roadway (30) and the half (½) ground pedestrian bridge (40).

As enlarged and shown as FIGS. 5 to 8 the four half (½) underground U-turn lanes (200E, 200W, 200S and 200N) include the half (½) overpass (50), the half (½) underground U-turn roadway (60) and the half (½) underground crosswalk (70).

Moreover, lanes and crosswalks of each structure enable vehicle and pedestrians to go straight, take a U-turn and take the crosswalk, respectively.

On the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) the half overpass (50) is constructed for going straight on a going-straight on a going-straight lane in one direction, and the half (½) underground crosswalk (70) is constructed in the other direction perpendicular to the half (½) overpass (50).

When the half (½) underground U-turn roadway (60) that is inclined toward the semi-underground on the third and fourth lanes is constructed on right and left sides in parallel, centering around the half (½) overpass (50), vehicles that couldn't take a left turn on the half (½) cloverleaf (100) takes a U-turn and drives on the half (½) underground U-turn roadway (60). It may be the same function as left-turning on the half (½) cloverleaf (100).

When the half (½) underground crosswalk (70) is perpendicular to the half (½) overpass (50) in the shape of “I” and connected to bidirectional sidewalks, it is constructed on the semi-underground to allow pedestrians to walk without obstacles to going-straight or U-turning vehicles.

As shown as FIG. 9, the side view according to the “example” illustrates structures including the half (½) overpass (50), the half (½) underground U-turn roadway (60) and the half (½) underground crosswalk (70) of the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) that is shown in the FIGS. 5 to 8 taken from the side.

Now, the nonstop traffic system using the half (½) U-turn lanes and the traffic method applied with the nonstop traffic system will be explained in detail.

Exemplary Embodiment

The loop-type traffic system that connects the half cloverleaf (100) to the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) is formed to allow lanes in each direction to be differentiated in comparison with other lanes, thus vehicles that are independently driving in one direction without obstacles to other lanes to go straight, take a right turn, take a U-turn and pedestrians to take the crosswalk nonstop in every direction. Then, only an example for one lane will be explained without repetition.

1). When Driving from the Half Underground U-Turn Lane (200W) to the Half Underground U-Turn Lane (200E).

Vehicles can arrive on the half (½) underground U-turn lane (200E) by going straight on the half (½) underground U-turn lane (200W) and then going straight on the half (½) underpass (20) constructed on the first and second lanes of the half (½) cloverleaf (100).

2). When Driving from the Half (½) Underground U-Turn Lane (200W) to the Half (½) Underground U-Turn Lane (200S).

Vehicles can arrive on the half (½) underground U-turn lane (200S) by going straight on the half (½) underground U-turn lane (200W), entering the half (½) underpass (20) constructed on the third and fourth lanes of the half (½) cloverleaf (100) using the first and second center lanes of the half (½) underground roadway (20), taking a right turn and then going straight using the half (½) underground U-turn roadway (30) constructed on the third and fourth lanes of the half (½) cloverleaf (100).

3). When Driving from the Half (½) Underground U-Turn Lane (200W) to the Half (½) Underground U-Turn Lane (200N).

Vehicles can arrive on the half (½) underground U-turn lane (200N) by going straight on the half (½) underground U-turn lane (200W) then going straight using the half (½) underpass (20) constructed on the first and second lanes of the half (½) cloverleaf (100), then taking a U-turn at a U-turning point after entering the half (½) underground U-turn roadway (60) constructed on the third and fourth lanes of the half (½) underground U-turn lane (200E), driving in a direction opposite to the driving direction, and going straight on the half (½) underground U-turn roadway (30) constructed on the third and fourth lanes of the half (½) cloverleaf (100) after making a right turn on the half (½) underpass (20) constructed on the third and fourth lanes of the half (½) cloverleaf (100).

4). When Driving from the Half (½) Underground U-Turn Lane (200W) to the Half (½) Underground U-Turn Lane (200W).

That is a lane in an opposite direction, vehicles can arrive on the half (½) underground U-turn lane (200W) that is an opposite lane by going straight on the half (½) underground U-turn lane (200W), entering the half (½) underground U-turn roadway (60) constructed on the third and fourth lanes of the half (½) underground U-turn lane (200E) that is located in front after going straight through the half (½) underpass (20) constructed on the first and second lanes of the half (½) cloverleaf (100), taking a U-turn at a U-turning point and driving in a direction opposite to the driving direction, then going straight on the half (½) underpass (20) constructed on the first and second lanes of the half (½) cloverleaf (100).

On the half U-turn lanes (200E, 200W, 200S and 200N), a traffic flow of the lanes that have different directions is the same process as the process of enabling vehicle to proceed to the half (½) U-turn lanes (200E, 200W, 200S and 200N) from the half (½) underground U-turn lane (200W). The nonstop traffic system using the half cloverleaf and the traffic method applied with the same can be applied to all lanes in common.

Pedestrians who decide to take the crosswalk can walk nonstop without obstacles to a traffic flow of other lanes by using the half (½) ground pedestrian bridge (40) in the shape of “H” of the half (½) cloverleaf (100) or the half (½) underground crosswalk (70) in the shape of “I” of the half (½) underground U-turn lanes (200E, 200W, 200S and 200N).

As described above, the nonstop traffic system using the half (½) cloverleaf and the traffic method applied with the same are explained with reference to the embodiments.

SIMPLE DESCRIPTIONS OF THE PLAN

The present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings.

FIGS. 1 and 2 are schematic plane views of a nonstop traffic system using a half (½) cloverleaf (100) according to an exemplary embodiment of the present invention.

INDUSTRIAL APPLICABILITY

The nonstop traffic system using the half (½) cloverleaf and the traffic method applied with the same according to the present invention can solve traffic problems by adopting the bisectional construction method for structures that can divide one structure, for example, the half (½) cloverleaf (100) or the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) into two sections, upper and lower portions, and then make the upper portion exposed on the ground and the lower covered underground, to differentiate the height and depth of each lane, thereby enabling vehicles to go straight, make a right turn and U-turn, and pedestrians to take the crosswalk nonstop all the time without obstacles to other lanes.

The structures according to the bisectional construction method can be reduced by half in height or depth. Thus, it is easy and efficient to construct the structures on every spots. Moreover, it can be harmonized with surrounding views and improve economical efficiency. It is the only way to replace the existing traffic system.

The loop-type system that can connect the half (½) cloverleaf (100) to the half (½) underground U-turn lanes (200E, 200W, 200S and 200N) is formed to construct structures easily even in places with narrow roadways, dense population and complex conditions. It can reduce a traffic jam or a traffic accident that may happen at existing intersections or lanes for the right-turn, left-turn and U-turn, and crosswalks with the establishment of road structure system. Moreover, it can save fuel and improve the flow of traffic without a time of waiting for traffic lights for changing driving directions.

Additionally, it can reduce the import of crude oil and production of carbon dioxide, by the adoption of Kyoto protocol, then cut air pollution.

It should be understood by those with ordinary skills in the art that various replacements, modifications and changes in the form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims.

Therefore, it is to be appreciated that the above described embodiments are for the purposes of illustration only and are not to be construed as limitations of the invention. 

1. A method of constructing a nonstop traffic system using a half cloverleaf, comprising: constructing a loop-type system to connect a half cloverleaf at an intersection to first, second, third, and fourth half underground U-turn lanes on roadways for left turns and U-turns, and crosswalks, said roadways extending in four direction, wherein said constructing comprises constructing semi-structures at the intersection or on the roadways for left-turns and U-turns, and crosswalks according to a bisection construction method.
 2. The method of constructing a nonstop traffic system using a half cloverleaf of claim 1, wherein the height of lanes of each structure are differentiated enabling vehicles to independently drive in one direction, if semi-structures including a half overpass, a half underpass, a half underground U-turn roadway and a half ground pedestrian bridge three-dimensionally are constructed to enable vehicles to go straight, take a right turn and a U-turn, and pedestrians to take the crosswalks nonstop at the intersection, thereby enabling vehicles driving in each direction to go straight, take a right-turn and U-turn and pedestrians to take the crosswalk nonstop without obstacles to other lanes.
 3. The method of constructing a nonstop traffic system using a half cloverleaf of claim 1, wherein the first, second, third, and fourth half underground U-turn lanes differentiated height of lanes enabling vehicles to independently drive in one direction, if semi-structures including a half overpass, a half underground U-turn roadway and a half underground crosswalk three-dimensionally are constructed to enable vehicles to go straight, take a right turn and a U-turn, and pedestrians to take the crosswalks nonstop, thereby enabling vehicles to go straight, take a right-turn and U-turn and pedestrians to take the crosswalk without obstacles to other lanes.
 4. The method of constructing a nonstop traffic system using a half cloverleaf of claim 2, wherein the half ground pedestrian bridge of the half cloverleaf is constructed at a point equivalent to half of the height (9.00 m the height from the ground of the half underpass to the half overpass of the half overpass from a point at which the half overpass is perpendicular to the half underpass, and at a point that an upper portion (4.50 m, the height from the bottom ground of the half (½) underpass of a median strip of the half underpass is horizontally in contact with the surface, wherein the half ground pedestrian bridge is constructed in the shape of an “H” (plane view) and a “T” (site view), if the point is horizontally connected to sidewalks in four direction to allow pedestrians to take the crosswalk nonstop in four directions without obstacles to other lanes.
 5. The method of constructing a nonstop traffic system using a half cloverleaf of claim 3, wherein the half underground crosswalk of the first, second, third, and fourth half Underground U-turn lanes is constructed in the shape of an “I” (plane view) by being perpendicular to the half overpass, half underground (1.50 m under the ground) at a point equivalent to half of lane height of the half overpass and connecting sidewalks on both sides enabling pedestrians to walk on both sides nonstop without obstacles to other lanes.
 6. The method of constructing a nonstop traffic system using a half cloverleaf of claim 2, wherein the bisection construction method divides structures including the half overpass of the half cloverleaf, upper and lower portions, makes the upper portion exposed on the ground and the lower covered underground, and differentiates the height of lanes in each direction in comparison with other lanes enabling vehicles to drive in each direction to go straight independently without obstacles to other lanes, make a right turn and U-turn all the time without obstacles to other lanes.
 7. The method of constructing a nonstop traffic system using a half cloverleaf of claim 2, wherein the bisection construction method divides structures including the half underpass and the half underground U-turn roadway of the half cloverleaf, upper and lower portions, makes the upper portion open on the ground and the lower buried underground, and differentiates the height of lanes in each direction in comparison with other lanes enabling vehicles to drive in each direction to go straight independently without obstacles to other lanes, make a right turn and U-turn all the time without obstacles to other lanes.
 8. A method of constructing a nonstop traffic system using a half cloverleaf, including a loop type nonstop traffic system that can connect a half cloverleaf to first, second, third, and fourth half underground U-turn lanes that are constructed in four directions centering around the half cloverleaf, and that can make a vehicle drive nonstop from the first half underground U-turn lane constructed in one direction among the lanes to the first, second, third, or fourth half underground U-turn lanes that are constructed in other directions wherein, when driving nonstop from the first half underground U-turn lane to the second half underground U-turn lane, vehicles can arrive on the second half underground U-turn lane by going straight on the first half underground U-turn lane and then going straight on the half underpass constructed on the first and second lanes of the half cloverleaf; when driving from the first half underground U-turn lane to the first half underground U-turn lane in an opposite direction, vehicles can arrive on the first half underground U-turn lane in a direction opposite to the starting direction by going straight on the first half underground U-turn lane, going straight on the half underpass constructed on the first and second lanes of the half cloverleaf, entering onto the half underpass constructed on the third and fourth lanes of the second half underground U-turn lane, taking a U-turn at a U-turning point and going straight, then driving along the half underpass constructed on the first and second lanes of the half cloverleaf; when driving nonstop from the first half underground U-turn lane to the third half underground U-turn lane, vehicles can arrive on the third half underground U-turn lane by going straight on the first half underground U-turn lane, then going straight through the half underpass constructed on the first and second lanes of the half cloverleaf (100), then taking a U-turn at a U-turning point after entering the half underground U-turn roadway constructed on the third and fourth lanes of the second half underground U-turn lane, on the opposite lanes such as the third and fourth lanes, taking a right turn on the half underpass constructed on the third and fourth lanes of the half cloverleaf, then going straight on the half underground U-turn roadway constructed on the third and fourth lanes of the half cloverleaf, vehicles can arrive on the third half underground U-turn lane by going straight on the first half underground U-turn lane, then driving on the half underground U-turn roadway constructed on the third and fourth lanes of the half cloverleaf after taking a right turn on the half underpass constructed on the third and fourth lanes of the half cloverleaf, then taking a U-turn at a U-turning point after entering the half underground U-turn roadway constructed on the third and fourth lanes of the fourth half underground U-turn lane, then going straight on the half overpass constructed on the first and second lanes of the half cloverleaf (100); and when driving nonstop from the first half underground U-turn lane to the fourth half underground U-turn lane, vehicles can arrive on the fourth half underground U-turn lane by going straight on the first half underground U-turn lane, entering the half underpass constructed on the third and fourth lanes of the half cloverleaf, taking a right turn, then going straight on the half underground U-turn roadway constructed on the third and fourth and lanes of the half cloverleaf.
 9. The method of constructing a nonstop traffic system using a half cloverleaf of claim 8, wherein, when driving from the second, third, or fourth half underground U-turn lane in one of three directions to the first, second, third or fourth half underground U-turn lane when proceeding from the first half underground U-turn lane to the first, second, third, or fourth half underground U-turn lane, vehicles can go straight, take a right turn and a U-turn nonstop without obstacles to other lanes, vehicles can arrive at their destinations by taking a U-turn or taking a right turn without left-turn.
 10. The method of constructing a nonstop traffic system using a half cloverleaf of claim 3, wherein the bisection construction method divides structures including half overpasses of the first, second, third, and fourth half underground U-turn lanes, upper and lower portions, makes the upper portion exposed on the ground and the lower covered underground, and differentiates the height of lanes in each direction in comparison with other lanes enabling vehicles to drive in each direction to go straight independently without obstacles to other lanes, make a right turn and U-turn all the time without obstacles to other lanes.
 11. The method of constructing a nonstop traffic system using a half cloverleaf of claim 3, wherein the bisection construction method divides structures including the half underground U-turn roadways of the first, second, third, and fourth half underground U-turn lanes (200E, 200W, 200S and 200N), upper and lower portions, makes the upper portion open on the ground and the lower buried underground, and differentiates the height of lanes in each direction in comparison with other lanes enabling vehicles to drive in each direction to go straight independently without obstacles to other lanes, make a right turn and U-turn all the time without obstacles to other lanes. 